Meghan Bartels of Newsweek discusses a discovery from the Kavli Institute of the first tidal disruption flare or “jet” that’s been produced due to a supermassive black hole consuming a star in space. “This is telling us the black hole feeding rate is controlling the strength of the jet it produces,” NASA Einstein Postdoc Fellow and lead researcher Dheeraj Pasham said.
Brooks Hays for UPI highlights research led by postdoc Dheeraj Pasham from MIT's Kavli Institute, that has captured the rare occurrence of “radio signals produced by a black hole devouring a star.” “This is the first time we've seen a jet that's controlled by a feeding supermassive black hole,” explained Pasham.
The Economist highlights MIT spinout ClearMotion, which developed a suspension system that utilized bumpy roads to generate electricity. Later, the team realized that their system also created a smoother ride, when ran in reverse. “The effect is to level out a rough road by pushing the wheels down into dips and pulling them up over bumps.”
A study from senior researcher Rolland Pellenq finds that grid-like cities retain more heat than those that are less-linear, due to the “Urban Heat Island” effect. “For new cities, or even neighborhoods, our findings can be used…in designing block layouts that would help optimize temperature,” Pellenq explains to Marlene Cimons of Popular Science.
MIT will partner with Commonwealth Fusion Systems in an effort to make fusion power a reality in 15 years. “MIT and CFS are hoping to facilitate a leap forward on several of these problems at once with a new superconducting material that will help make more efficient magnets to control the plasma,” Eric Limer writes for Popular Mechanics.
In this opinion piece published by The Boston Globe, Vice President for Research Maria T. Zuber writes that fusion energy is within reach: "The MIT design uses established science for the plasma confinement, and thus puts fusion power plants within reach on a faster time-scale than previously thought possible."
This April, NASA will launch the Transiting Exoplanet Survey Satellite, or TESS, which will measure the masses of at least 50 “potentially Earth-like worlds,” writes Irene Klotz for Scientific American. “We’re finding the particular star that actually potentially hosts an exoplanet around it,” said senior research scientist George Ricker, the lead scientist on TESS.
The Nature Podcast, hosted by Adam Levy and Shamini Bundell, highlights research from the Haystack Observatory and Prof. Li-Huei Tsai’s findings around Alzheimer’s and its connection to brain waves.
Led by senior research scientist Rolland Pellenq, students in the School of Engineering developed a model “that links a city’s ‘texture’ to its night-time UHI (Urban Heat Index),” writes Laurie Winkless for Forbes. The team hopes their research will influence future urban development, especially in very hot or cold climates.
Alan Rogers of MIT's Haystack Observatory co-authored a study that identifies the earliest traces of hydrogen in the universe. The gas is “from 180 million years after the Big Bang,” writes Elise Takahama for The Boston Globe, which suggests that stars would have appeared around this time, creating a “cosmic dawn.”
Research published in Science demonstrates the ability of photons to bind together in a way previously thought impossible – creating a new form of light. “The photon dance happens in a lab at MIT where the physicists run table-top experiments with lasers,” writes Marissa Fessenden for Smithsonian. “Photons bound together in this way can carry information – a quality that is useful for quantum computing.”
Writing for Newsweek, Katherine Hignett reports that for the first time, scientists have observed groups of three photons interacting and effectively producing a new form of light. “Light,” Prof. Vladan Vuletic, who led the research, tells Hignett, “is already used to transmit data very quickly over long distances via fiber optic cables. Being able to manipulate these photons could enable the distribution of data in much more powerful ways.”
Research by Physics PhD candidate Sergio Cantu has led to the discovery of a new form of light, which happens when photos stick together, as opposed to passing through one another. “’We send the light into the medium, it gets effectively dressed up as if it were atoms, and then when it turns back into photons they remember interactions that happened in the medium,” Cantu explains to Leah Crane at New Scientist.
MIT physicists have created a new form of light that allows up to three photons to bind together, writes Daniel Oberhaus for Motherboard. While the research is experimental, Oberhaus writes that the trio of photons “are much more strongly bound together and are, as a result, better carriers of information” than other photonic qubits.